Apparatus for closing, sewing, and sealing bags



May 30, 1939. 2,160,059

SEWING, AND SEALING BAGS R. N. C UNDALL APPARATUS FOR CLOSING l4 Sheets-Sheet 1 Filed Npv. '2, 1932 Haber! N. C'undall -ATTORNE y 30, 1939- R. N. CUNDALL 2,160,059

SEWING, AND SEALING BAGS APPARATUS FOR CLOSING,

Filed Nov. 2, 1932 14 Sheets-Sheet 2 INVEN'TOR Rpberf N. Cunaall ATTO R N. CUNDALL 2,160,059

APPARATUS FOR CLOSING, SEWING, AND SEALING BAGS Filed Nov. 2, 1932 14 Sheets-Sheet 35 May 30, 1939.

; INVENTOR Robert N. Cunda ATl ORNEY May 30, 1939. R. N. CUNDALL 2,160,059

APPARATUS FOR CLOSING, SEWING, AND SEALING BAGS Filed Nov. 2, 1932 14 Sheets-Sheet 4 |NVE NTOR Z3 Hoberl N. Cundall May 30, 1939. R. N. CUNDALL 2,160,059

SEWING, AND SEALING BAGS APPARATUS FOR CLOSING,

14 Sheets- Sheet 5 Filed Nov. 2, 1932 a Md mm m. m /m I M l y 1939- R. N. CUNDALL 2,160,059

SEWING, AND SEALING BAGS APPARATUS FOR CLOSING,

Filed Nov. 2, 19 52 14 Sheets-Sheet 6 O INVENTOR Hoberl M Cundall ATTORNE m 6 9 7. b m a O y 30, 1939- R. N. CUNDALL 2,160,059

APPARATUS FOR GLOlNG, SEWING; AND SEALING BAGS Filed Nov. 2, 1932 14 Sheets-Sheet 7 i: I I03 71.14. 0 I I. I 2! a f E g, 1/3 g a 5; no 1/0 1/? i I [/2 l0! l0/ L5 l 119% y 5 O 0 ho) 1 9, r I

1 102 i IZI INVENTOR ATTORNEY y 1939- R. N. CUNDALL 2,160,059

APPARATUS FOR CLOSING, SEWING, AND SEALING BAGS Filed Nov. 2, 1932 14 Sheets-Sheet 8 INVENTOR Haber! 1V, Cundall BY W ATTORNEY May 30, 1939. 2,160,059

SEWING,v AND SEALING BAGS R. N. CUNDALL APPARATUS FOR CLOSING,

Fi led Nov. 2, 1932 14 -Sheets-Sheet 9 ZZZ I lioberl M C'undall l IIIIL WW/ y ATTORNEY v y 30, 1939- R. N. CUNDALL 2,160,059

SEWING, AND SEALING BAGS APPARATUS FOR CLOSING.

Filed Nov. 2, 1932 i4 Sheets-Sheet 10 INVEN'TOR Haber! M Cundall ATTORNEY '(IIIIIIIIIIII m Low F-IIP.

M y 30, 1939 R. N. CUNDALL 2,160,059

SEWING, AND SEALING BAGS APPARATUS FOR CLOSING.

Filed Nov. 2, 1952 14 Sheets-Sheet ll m H mm m m lNwm May 30, 1939. R. N. CUNDALL 2,160,059

- APPARATUS FQR CLOSING, SEWING, AND SEALING BAGS Filed Nov. 2, 1952 l4 Sheets-Sheet l2 INVENTOR Koberl N. Cundall 75*.55 A I 1 BY May 30, 1939. R. N. CUNDALL. 2,160,059

, SEWING, AND SEALING BAGS Filed Nov. 2, 1952 APPARATUS FOR CLOSING l4 Sheets-Sheet l5 NINIIIIIIIIIIIIBIHIIIH- INVENTOR Haber? N. Cundall y @wk ATTORNEY y 30,- 1939- R. N. ACUNDAL L 2,160,059

APPARATUS FOR CLOSING, SEWING, AND SEALING BAGS Filed Nov. 2, 1932 14 Sheets-Sheet l4 ti "1 5. H

i 1 in INVENTOR Haber! N. Cundall ATTORNEY Patented May 30, 1939 UNITEDSTATES E 1 2,160,059." r 'APPARLATUSFOR CLOSING, some; SEALING mes Robert N. Cundall, Iackawanna, N. Y., assignor H v; I

to Bagpak, Inc., a corporation of Delaware Application November 2, 1932, Serial No."640 ,"i58" 31 Claims. 01. 112-11) Y My invention relates to apparatus for filling,

closing, sewing and sealing open-mouth bags, such for example as paper bags of relatively large size.

adapted to contain as much as 100 pounds or more of cement or; other pulverulent or granular material.

Prior to my invention, there has been no sat- 1 isfactory machine for accomplishing the purpose j recited above, and it has'been necessary to resort j to manual-filling, closing, sewing and sealingoperations. it will be realized, however, that with bags of the size indicated hereinabove, such operations are performed manually only with excessive and tedious labor. I 5 It is therefore an objectof my invention to provide apparatus for mechanically accomplishing the purpose set forth. My invention has for further objects numerous improvements in operative advantages and construction, both'with re- 2o spect'to the apparatus as a whole and the several f portions thereof; as will hereinafter be found to obtain. v

In order that my. invention may clearly be set forth and understood, I now describe, with ref- 5 erence to the drawings, accompanying and forming a partof this, specification, a preferred form and manner in which it may be embodied. In these drawings, v N Fig. 1 is a side-elevationalyiew of the entering 30 end of a machine constructed in accordance with my invention, including mouth closing and sewing stations; I Fig. 2 is a side-elevational view of the remainder of the machine, showing tape-applying, a6 squeezing and severing, stations;

Fig. 3..is an .end-elevational view of the apparatus shown in Figs. 1,and' 2, taken along the. line 3-3 of Fig. 2, illustrating a portion of the driving mechanism. for. the: apparatus;

Fig. 4 is a vertical sectional view, taken non;

.being taken on the line" |s j1s '1 r gij a; Fig. 16 is a horizontal sectional' lviewf'. the direction oiarrows fli -J6 of Fig.

the line 11-41 01' mars; i

Fig. 12 a si iiari'viev. but ts 1 *rr g; the opposite side, of a portionfoi apparatus shown ..in Fig. 11;

Fig. 13 is a aqv i wof,b osing mechai nism, taken in he'directionjofar wsfllHli 'on Fig. 1; I 11 Fig. 14 is a vertical sectional view oi tion ofthe" a paratusshown in F1 -1 Fig. 15, is a viewigenerally but showing'the parts in a different position illustrating apparatus iior grippin 'fth'e 'bfagsdun ing the sewing operationy,

fFig. 17 is a. vertical sections?tigvtgtakei jea Fig. 1a is an 'endelevational,"'iew 1' a U o. weh e sewing head and carriagethereion takenon he 20 line l8l8'oi Fig. 1; Fig. 19 isa verticallseetionalfv taken on'the linen-la off Fig.',18;."

Fig. 20. isan end-elevation'al yiewfof tap 'ap-' plying mechanism forming a. part'oFthQ- appa ratus illustrated inFig; 2;, 7;

Fig. 21 is ahorizontalsectional view oil and} tion of the same} taken, onjfthe line[ 2lf,2l1fo f Fi 2;

Fig. 22 is an elevatio a 1[view.fnfan enlarged scale, of a portion of th'e; apparatus illustrated in Figs. 20 and 21;}

Fig. 22a is,a. planjview,,shoW1li8v th ge a1 arrangement, of gripping used in connection with thetape applying mechanis difierentposition; I H I 6 isgasectional view,taken on g .1 c ten akeninj the directiori of the arr s g9 and 10a're' detailed elevational spout and mechanismassociat Y entering en'dfof the machine is a vertical sectional view of mac closing and gusseting the mout n warm-1 j ail i1 .of.=-1the1me.c an s own 1, in i 4,; h ,n in a 3 Q "iel vatmha'l view offal mafi who n i the ..i ni0 1 not do Fig. 29 is a'plan w i apparatus shown in Fig 27; marmtsmfasu- .13

" ligssap '801=is aZ front-eleyationa svi wmf 1-' we;

35 d bag moves forward again on the conveyor B and The machine as a whole This machine consists of a number of units adapted to operate in sequence upon a bag. Referring to Figs. 1 and 2, the general organization is as follows:

The bag is filled while attached to a spout at a station A. After being filled it moves upon a conveyor B to an idle station desgnated as C.

The conveyor B moves intermittently and advances a step after each bag is filled. The filled bag moves from the idle station C to a closing station D where its mouth is closed and gusseted. The mouth is held in this condition while the bag advances to an idle station E.

At the station E the bag comes into the grip of belts F, shown in Fig. 16. At the next step of the machine, the bag moves upon the conveyor B to an idle station G, still in the grip of the belts F. The next movement of the bag brings it to a sewing station H. While the bag is at rest at the station H, its lips, which project above the belts F, are sewed by a sewing head 'I which is mounted upon a reciprocated carriage and traverses the bag. When the sewing head has reached the end of its travel, which is to the right of its position as shown in Fig. 1, the

is accompanied by the sewing head.

In thus moving forward, the bag leaves the grip of the belts F and approaches the grip of a second pair of belts J, shown in Fig. 22a. The next forward step of the bag brings its mouth beneath a mechanism K, shown in Fig. 2, which applies a pasted tape over the mouth of the bag and over the stitches just previously sewed therein. The next forward step of the bag brings its mouth, now covered by the pasted tape, between the jaws of a squeezing device L which, while the bag is stationary, acts to press and squeeze the pasted tape on to the mouth of the'bag.

Further forward movement of the bag brings it into the grip of a second squeezing device L identical with the first squeezer L. It will be understood that as many such squeezing devices can be included as may be found necessary to produce a firm grip of the tape.

At each period of rest of the conveyor B, a bag is filled and takes its place in the procession of bags, so that a continuous series of bags passes through the machine. These bags are joined together by the stitching applied at the station I and also by the pasted tape applied at the station K. To sever the combined tape and stitching a station M is'provided. At station M the tape and stitching connecting the bags is severed and the end bag at its next forward step is delivered out of the machine.

The mechanisms at the various stations operate in timed relation to the movements of the conveyor B. These mechanisms are driven from a cam shaft N, shown in Figs. 1, 2 and 3, which extends along the machine at its right hand side as viewed from the entering end.

Driving mechanism The driving mechanism is best shown in Figs. 3, 4, 5 and 6. A motor (not shown) operates through a belt 8 and a pulley 9 to drive a shaft l which operates through a reducing gear II to drive a shaft I2 journaled at right angles to shaft ||l. The'shaft I2 runs continuously and drives one member I3 of a clutch I4 mounted upon a shaft I5. The member I3 is free to rotate about the shaft I5 until the clutch I4 is engaged, when the shaft I5 rotates in unison with the member l3.

Mounted on the shaft I5 is a segmental gear I5a keyed to the shaft I5 and a segmental gear |5b which is free to rotate about the shaft I5 but is restrained 'by the action of a coil spring I5c,

one end of which is rigidly secured to the shaft I5. The spring I50 tends to maintain the segment I5b in abutting, following relation to the segment I5a, as shown in Fig. 4. The segments |5a and |5b are peripherally in alignment.

Mounted above the shaft I5 and parallel thereto is a countershaft I6. A pinion I1 ih keyed to the shaft I6 and meshes with the segments I5a and I5b.

An arm I8 keyed to the shaft I6 has secured at its outer end a cable or sprocket chain I9. This cable runs around a pulley 20 mounted upon a shaft 2| and then passes over an idle pulley 22. A counterweight 23 is suspended from the opposite end of the cable I9 for the purpose of maintaining a tension upon the cable I9 and returning the parts. The pulley 20 has a ratchet connection with the shaft 2| and rotates the latter only in a counter-clockwise direction, as viewed in Figs. 4 and 5. Due to angularity between the cable l9 and the arm la, a full rotation of the arm I8 draws the cable I9 first in one direction and then in the other with substantially sinusoidal acceleration and deceleration, and thus causes the shaft 2| to rotate intermittently, each advancing motion being sinusoidal in character.

' driven uniformly and continuously around the shaft IS, the periods of rotation and rest of the shaft 2| would be equal in duration. However, it is desired to make the periods of rest of the shaft 2| of relatively long duration with respect to the periods of rotation, for the reason that the periods of rest correspond to various timeconsuming operations such as the filling and sewing of the bag, and if the periods of rotation, which correspond to the movements of the bags along the conveyor, were of equal duration, the output of the machine would be considerably reduced.

The purpose of the segmental gears I5a, and ISD is to provide for relatively short periods of rotation of the shaft 2| and relatively long periods of rest of the same, and the manner in which the mechanism just described operates to achieve this result is as follows:

In Fig. 5, the arm I8 is shown in its lower dead-center position with respect to the pull exerted by the counterweight 23, the counterweight 23 being at the bottom of its travel. The keyed segment I50. is out of mesh with the pinion I1 and is passing downward on the lefthand side of the shaft I5 as viewed in Fig. 5; Due partly to the fact that the strength of the spring |5c a vertical shaft 36. Each of the shafts as carcauses it to rotate the pinion l1, thus swinging the arm l8 in a clock-wise direction as viewed from-the point of view of Fig. 5.

The shaft 2| then rotates with sinusoidal ac-' celeration and deceleration, passing through the position shown in Fig. 4a, until the arm |8 reaches its upper dead-center position directly opposite to that in which it is shown in Fig. 5. At this point, rotation of the shaft 2| ceases. Also .at this point, the keyed segment I50, has just come into mesh with the pinion |1. This is necessary, for the reason that if the arm l8 passed its upper dead-center position during such time as the pinion H were in mesh only with the follower segment l5b the combined effect of the counterweight 23 and the spring |5c would cause the follower segment |5b to travel ahead of the keyed segment |5a and the arm |8 would rapidly return to its lower dead-center position in which it is shown in Fig. 5. However, the intermeshing of the keyed segment |5a with the pinion |1 limits the return of the arm l8 under the influence of the counterweight 23-.

Very shortly after the keyed segment |5a comes into mesh with pinion I1 the follower segment |5b passes out of mesh with the pinion l1 and under the influence of the spring |5c returns to a position behind the segment l5a, in which position it is shown in Fig. 4. Further rotation of the keyed segment I511. brings the arm I8 back to its lower dead-center position in which it is shown in Fig. 5, the segment |5b following the segment |5a only a short distance after the latter has passed out of mesh with the pinion 1. The apparatus is now returned to the position in which it is shown in Fig. 5, the shaft 2| remaining stationary until the keyed segment |5a again strikes the rear face of the follower segment |5b-. Y

In the specific instance illustrated in the drawings, the pinion I1 is provided with 24 teeth and the segments I50. and |5b are provided with 9 teeth and 15 teeth, respectively, or a total of 24 teeth, out on a circle of sufficient size to accommodate a possible total of 36 teeth. Due to this relation and due-also to the fact that the arm l8 rotates the shaft 2| during only one-half of its complete circle of 360 around the shaft 6, the shaft 2| is caused to have a motion period of relatively 120 and a rest period of relatively 240; that is to say, the rest periods of the shaft 2| are twice as long as its motion periods.

,The purpose of the brake 24 is simply to prevent the arm. |8 from passing itslower deadcenter position under the influence of the spring |5c. The brake-shoe 24 is pivoted at 25 and is urged upwardly by a compression spring 26 mounted on a rod 21 having a stop 28 and passing through a pivoted slide 29. The upper surface of the brake-shoe 24 in the position shown in Fig. 5 is arcuate with respect to the center of the shaft l6, but as the arm l8 passes. on, the left-hand end of the brake-shoe 24 moves slightly upward into the position in which it is shown in Fig. 4 under the influence of the spring 26, the upward travel of the left-hand end of the brake-shoe 24 being limited by the stop 28.

The shaft 2| is parallel to the shafts l5 and 6. On the right-hand end on the shaft 2| is mounted a pulley 30, shown in Fig. 3, which drives the belt 30' of the conveyor B. A sprocket 3| is mounted on the shaft 25 and through a sprocket chain 32 drives a shaft 33. The shaft 33 carries bevel pinions 34 meshing with bevel gears 35, each bevel gear being mounted upon shown in Figs. 1, '1, 8, 9, 10, 35 and 36.

ries a series of pulleys 31 which act to drive lateral supporting belts 38, which belts support the bag against lateral tipping and assist in accelerating and decelerating all portions of the bag equally along its vertical axis.

It will be noted from Fig. 3 that the shaft l5 has at its right-hand end a bevel pinion 40 meshing with an equal sized bevel pinion 4| which is keyed to the cam shaft N. As a result, each revolution of the shaft I5 produces a period of rest and a period of movement of the conveyor B and simultaneously one complete revolution of the cam shaft N. One revolution of the cam shaft N will produce a complete cycle at each of the operating stations.

Bag filling mechanism The spout and its associated parts are best This mechanism consists of a hopper 5|] terminating in a spout 5|. The hopper and spout are integrally joined and have mounted thereon lugs and 5|. Pivoted to the lugs are levers 52 and 53 pivotally secured at their opposite ends to the fixed frame 54. This mounting permits the spout to move vertically, and the weight of the hopper and spout is counterbalanced by a weight W secured at one end of an extension 53 of the arm 53.

A bag 60 is brought up over the spout, as shown in Figs. 8 and 9, with its sides between the These clamping members are pivotally mounted on shafts 6| and have clamping surfaces 62 eecentric to the shafts 6|. When the clamps 6| are lowered, the clamping surfaces 62 press the bag 60 and hold it against thespout wall. In this condition the weight of the bag and its contents serves to intensify the clamping effect due to the eccentricity of the clamp surface 62. The clamps 6| are initially held in raised position to provide clearance beween their gripping surfaces and the spout wall by a pair of latch members 65, and are thus shown in Fig. 7.

As soon as the operator has brought the bag into the requisite position he presses upwardly a member 66 which serves to force apart the lower ends of the latch members 65,, thus withdrawing the upper ends of these members from under a pair of cooperating levers 61. The 1evers 61 support the clamps 6| through cranks 68 and rods 69. Accordingly, when the member 66 is pressed upwardly, with the effect indicated above, the clamps 6| drop and engage the bag.

At this time pulverulent material may be dumped from any suitable device into the hopper 50. The material enters into the bag which is at this time suspended from the spout and the weight of the material tends to overcome the effect of the counterweight W and thus tends to draw the spout downwardly. During this time the conveyor B is stationary but the shaft N is rotating. Pivotally attached to the arm 53 is a rod 10. At the lower end of this rod (Figs. 35 and 36) is a cam follower 1| which, after the bag receives a small amount of material, is caused to bear upon a cam 12 keyed to the shaft N. The cam 12 is provided with cut-away portions or recesses 13, 14 and 15 and with a constant radius portion 16.

With the weight of the hopper plus the weight of the material in the suspended bag overcoming the efiect of the counterweight W, rotation of the cam I2 permits the follower II, the rod I0, the arm 53, the hopper 50 and the bag 60 to drop at each of the cut-away portions I3, I0 and I5, thus jogging the bag and causing its contents to settle during the filling operation.

At the time the follower II enters the last cut-away portion I the spout is in its lowermost position, the bag is full and is resting upon the conveyor B. At this moment a rod 00 (Figs. 7, 33 and 34) actuated by a cam 8| on shaft N is thrust upwardly and strikes the end-face 82 of an arm 83 mounted upon a shaft 80.

The follower II bears upon the surface of the cam I2 only when there is suflicient material within the hopper 50 or the bag suspended therefrom to raise the counterweight W, the weight of the empty bag alone being insumcient to raise the counterweight W and lower the hopper 50 and spout 5I.

The configuration of the cam BI is such that the rod 80 is lowered prior to the time when the weight of material in the bag or the hopper 50 causes the latter to descend against the action of the counterweight W, and the raising of the rod 80 normally occurs at the time when the cam follower II traverses the cut-away portion I5 of the cam I2; in other words, after the bag has been filled and settled and the hopper 50 and spout 5| are in their lowermost positions, the counterweight W being raised.

Raising the clamping surfaces 62 and releasing the bag from the spout 5I then permits the latter to rise clear of the bag under the action of the counterweight W, the cam follower II rising clear of the cam I2; where it remains until the next bag is being filled.

The shaft 80 is -journaled in a pair of lugs 85 at the rearward end of the spout of hopper Keyed to the shaft 80 are a pair of crank arms 85 which act through adjustable draw rods 86 and crank arms 81 to turn the shafts BI and release the clamps 0 I thus permitting the spout to rise clear of the bag under the action of the counterweight W. The conveyorB then begins its forward movement to carry the filled bag out from under the spout.

Closing and gusseting mechanism It is desirable that the mouth of the bag be closed and gusseted and that this be done uniformly through an indeterminate series of bags. The gusseting produces a bag of uniform width throughout its length, shortens the length of the closing seam, and strengthens the entire closure at the bag mouth. The mechanism shown at station D of Fig. 1 accomplishes this purpose. This mechanism is illustrated in further detail in Figs. 11 to 15, 31, 32, 41 and 42.

The movement of the conveyor B brings the filled bag directly under a vertically reciprocable head I00. This head includes a pair of plates IM and a pair of fingers I02 moving at right angles to "the direction of motion of the plates. With the parts in the position shown in Fig. 15, the head moves downwardly carrying the plates IOI into the mouth of the bag but with the fingers I02 lying outside the bag mouth as shown in Fig. 1. The plates IOI are mounted to swing about shafts I03 and are geared together so that a swinging movement of one produces an equal swinging movement of the other.

Extending upwardly and to' the left of the lefthand shaft I 03 as shown in Fig. is an arm I00 terminating in a substantially horizontal portion I05. The downward movement of the head brings the portion I05 of the arm I04 into contact with a lug I06 which is yeldably biased against vertical downward movement. The effect of contact between the lug I06 and the member I05 is to produce a yielding, diverging movement of the plates IOI. This movement spreads the bag mouth into rectangular form.

The fingers I02 are mounted upon shafts II 0 journaled in lugs III on the head I00. At the opposite ends of the shafts IIO are a pair of intermeshing gear segmentsII2 (Fig. 14). The segments II2 are extended on the sides of shaft IIO opposite to the toothed surfaces and these extended ends are joined by a tension spring I I3. Downward movement of the head I00 carries the segments I I2 into contact with a fixed adjustable lug II I, shown in Fig. 11. Further movement of the head I00 after contact is established between the segments II2 and the lug H0 causes the segments to swing, rotating the shafts I I0 and forcing the fingers I02 inwardly. The downward movement of the fingers I02 presses the ends of the spread bag mouth inwardly and draws the plates IOI toward each other against the yielding resistance of the lug I06, thus forming a gusseted closure of the bag mouth.

It will be seen from Fig. 14 that when the outer ends of the segments II2 are rocked below the horizontal center lines of the shaft IIO a toggle action takes place and the segments arrive at a state of stable equilibrium under the action of spring I I3. This condition retains the fingers I02 in their inward position. At this time the head I00 begins an upward movement which permits the plates I0! to remain in mutual juxtaposition and the fingers I02 remain in inward position for the reasons just above noted.

Means are provided to hold the mouth of the bag in its closed, gusseted position after withdrawal of the plates IM and fingers I02 by the upward movement of the head I00. Such means comprises clamping members I20, shown in Figs. 11, 12 and 15. The members I are mounted upon arms I2I which arms are free to rotate about and slide along a pair of shafts I22. Extending from the opposite side of the arms I2I are lugs I23 carrying pairs of rollers I20, each pair engaging on opposite sides of a swinging rail I25. Each rail I25 extends between a pair of bell-cranks I20. Each pair of bell-cranks is keyed to one of the shafts I22. The pair of bellcranks I26 at the entering end of the machine are connected by a rod I2! placed and proportioned to produce equal rocking movement of either pair of bell-cranks I26 upon actuation of the other. I

Considering Figs. 11, 12 and 13 it will be seen that the parts just described provide means for rocking the clamping members I20 toward each other and permitting them to travel along the rods I22 whether in their open or closed position. The opening and closing movement of the clamps is produced by a rod I28 connected to one end of the forward right-hand bell-crank I26 as viewed in Fig. 12.- The rod I28 is actuated by a cam I29 shaft N as shown in Figs. 39 and 40. The weight of the head is counterbalanced by a counterweight I53 which acts through a cable I54to draw the head upwardly. As the head I00 approaches its upward limit of movement the gear members II2 contact a fixed surface II2 on the machine frame and continued upward movement of the head rocks the segments in a direction to move the arms I02 outwardly. As soon as the member I05 passes out of contact with the yieldable lug I06 the plates I return to their converging relation. This return movement is facilitated by any suitable tension device (not shown),

Referring to Fig. 1 it will be. noted that the clamping members I2I, which are mounted by 22I' to a pair of link frames 222 which are pivmeans of sleeves I2I' on the rods I22, have an upwardly projecting lug I60 which engages a rod I6I which is pivoted at its opposite end I62 to the reciprocating carriage on which is mounted the sewing head to be described more fully hereinbelow. Cables I63 are also attached to the sleeves I2I',passing over the pulleys I63 to a counterweight I64. The action of these parts is as follows:

The counterweight I64 draws the members I 2| to their right hand limit of motion opposite to that in which they are shown in Fig. 1. While in that position, the closing head I00 moves downwardly, spreading and gusseting the mouth of the bag. As the gusseting operation is completed the clamping members I2I move inwardlyand hold the mouth closed. During this time the carriage on which the sewing head is mounted has moved forwardly until a cam surface I6I' at the forward end of the rod I6I engages the inclined surface I6I" on the lug I60 and rides up over the inclined surface permitting the lug I60 to drop .into a notch I10 on the rod I6I. As the head I00 moves upwardly and clears the mouth of the bag the forward motion of conveyor B is resumed and is accompanied by a movement in the same direction and at the same speed on the part of the sewing head carriage. Due to the engagement of the lug I 60 in the notch I10, the sewing head carriage through the rod I6I draws the clamping members -I2I in the direction of the motion of the conveyor. As the sewing head reaches its leftward limit of motion an inclined surface I1I on the rod*I6I engages a roller I12 mounted on the machine frame and this engagement lifts the right-hand end of the rod I6I, disengaging the lug I60 from the notch I10. The clamping members at this time are spread apart by the cam I29 and are returned to their righthand position by the counterweight I64.

Sewing head and gripping belt The conveyor belts B are brought into motion as previously described by a sinusoidal acceleration. In order to secure uniform and accurate spacing of stitches it is necessary that the sewing head traverse the bag at a uniform speed. It is therefore impossible to pass the bag through the head by means of the conveyor motion. The expedient adopted herein is to. traverse the car-' of spring impelled frames 20I, the spring presrure being obtained by means of coiled springs 202 and bolts 203 which bolts bear against the frame members 20 I. These members carry a series of pulleys 204 which are placed close together and opposite each other in pairs. The

The bag mouth must be held the closing head into the grip of the belts 200.'

The belts are driven through mechanism to be described later from the same source as the conveyor B and move in absolute synchronism with it.

Mounted above these belts is a carriage 220 (Figs. 18 and 19). Links 22I are pivoted to each end of the carriage at either side thereof, and these links 22I are pivoted at their upper ends otally mounted at 223 to a supporting frame 2230. Two pairs of links 224 are pivoted at their lower ends to the fixed frame of the machine and at their upper ends to the central portions of the links 22I. As a result, the carriage 220 may be given a horizontal reciprocation in a single plane without encountering a sliding friction.

Mounted on the carriage 220 is an electric motor 230 which through a belt 230 drives a shaft 23I. Sleeved on one end of the shaft 23I is a pulley 232 which through a belt 233 drives a sewing machine 234. The pulley 232 has a clutch connection 235 with the shaft 23I so that the electric motor may run constantly and the sewing machine be connected and disconnected therefrom by means of the clutch 235. The clutch has an actuating lever 236 to which a spring 231 is connected. The spring tends'to hold the clutch-actuating lever in a position to disengage the pulley 232 from the shaft 23I. A solenoid 238 is provided and an armature 239 ccoperating with the solenoid is secured to the lever 236.

On the sameframe which supports the solenoid is a ratchet bar 240 which is pressed into engagement with the free end of the lever 236 by means of a leaf spring 24I. When thesolenoid 238 is energized it attracts its armature 239 which draws the lever 236 against the action of spring 231 and brings the clutch into engagement driving the sewing machine from the motor. The energization of the solenoid is only momentary. The lever 236 engages the ratchet bar 240 and is held in engaged condition after the solenoid is de-energized. The solenoid is energized at the correct moment by means of a switch operated from the cam shaft'N and by various connections forming no part of the present invention and not here shown.

The energization occurs with the carriage in the position in which it is shown in Fig. 19, the bag being just clear to the right of the sewing head 234. The sewing action begins as the conveyor B comes to a stop and the beginning of the sewing action is accompanied by a movement of the carriage 220 to the right from the point of view of Fig. 19. As the carriage moves to the right, traversing the bag, a cam end 242 on the ratchet bar 240 is brought into contact with a bar 243 mounted on an arm 243a fixed to the frame 223a. This engagement rocks the ratchet bar and releases the lever 236 which is then drawn by spring 231 into non-engaging position. The sewing machine ceases operation just as soon as it travels a short distance past the rear end of the bag being sewed.

Referring to Fig. 3-, it will be noted that there is a cam 250 keyed to the shaft I5. A lever 25I has a follower 25I' (shown in Fig. 43) bearing on this cam. The lever is for=convenience pivotally mounted on an extension of the shaft 20. The upper end of the lever 25I is pivotally attached to a draw rod 253. At the free end of the draw rod is secured a sprocket chain 254 which passes over a sprocket 255 on a shaft 256, which shaft 256 extends transversely of the machine. The free end of the chain 254 carries a counterweight 251. Keyed to the shaft 256 are sprockets 258. A second shaft 259 is parallel to the shaft 255 and carries sprockets similar to the sprockets 258. Chains 260 pass around the sprockets 258 and the sprockets on the shaft 259. The carriage 220 is connected to a link in each of these chains by means of lugs 250.

The mechanism just described operates as follows: rotation of the cam 250 rocks the lever 25l which pulls the rod 253 and accordingly through the chain 254 rotates the shaft 256 in a counterclockwise direction as viewed in Fig. 19. The rotation of this shaft advances the chains 260 drawing the carriage 220 to the right. The counterweight 251 acts to return the. carriage, meanwhile maintaining the follower on the rod 25i in contact with the cam 250 which controls the movement of the carriage.

It will be obvious that one complete traverse of the sewing head carriage 220 occurs at each revolution of the shaft l5 and of course at each revolution of the shaft N. The action of the sewing head is therefore cyclically synchronized with the action of the other operating stations, and the configuration of the periphery of the cam 250 is made such that the movement of the carriage 220 to the right (during which time the sewing head 234 traverses and stitches the stationary bag) is uniform straight-line motion, while on the reverse stroke (the bag now movin on the conveyor B) the movement of the carriage 220 is exactly synchronized with the sinusoidal movement of the conveyor B. 1

The sewing head 234 is pivoted at points 210 and 2H to lugs 21la and 21ib depending from the carriage 220. Preferably, but not necessarily, the axis of the pivots 21D and 21I passes through or substantially through the center of gravity of the head 234, which is free to rock about this axis. The sewing head 234 is biased toward a vertical position by any convenient means, such for example as a spring 21Ic located between one side of the head 234 and an extension 21ld of the lug 21), and is prevented from turning past this position by a stop 21le attached to the lugs 21la and 21112 on the other side of the head 234. As the head traverses the bag its needle 212 will from time to time enter the material of the bag and since this material is rigidly held by the clamping belts 250 the nee dle may not move relatively to the material while in engagement therewith.

The carriage 220, however, is continuously moving. My construction permits the sewing head 234 to rock about the axis of its pivots 210 and 2H until the needle in the sewing action is withdrawn from the material, at which time the head 234 returns once more into a vertical position.

It will be understood by those familiar with the art that the sewing head is provided with suitable feeding mechanism, such as a feed dog 280, cooperating with a presser foot 28l, to advance the material to be sewed through the head in intermittent forward motions, the length of which determines the stitch spacing. The insertions of the needle 212 through the material occur only during the intervals between the successive forward movements of the material caused by the feed dog 28!).

In the present instance, however, the feed dog 280, instead of advancing the material through a stationary sewing head, helps to advance the sewing head along the stationary material to be sewed. The manner of operation may readily be understood from the following exposition.

It has been set forth hereinabove that the sewing head carriage traverses the bag with uniform straight line motion. :In a typical instance, the relative speeds of the carriage 220 and the needle 212 of the sewing head 234 may be adjusted to give a stitch spacing of, for example, A"; that is to say, the needle 212 enters the material to be sewed at points separated by /4" spaces. The time which it takes for the needle 212 to enter the material, move forward to its point of deepest penetration, and move back to clear the material, is approximately one-half of the time it requires for carriage to move forward A and during this time that the needle is in engagement with the material being sewed there can, of course, be no relative movement between the material and the presser foot 28L During this period also, the feed dog 280' is out of engagement with the material being sewed, and in the present instance is moving back nut of engagement with the material being sewed for the purpose of making a subsequent forward stroke.

Thus at the moment thecarriage 220 has propressed 4;" past a stitching point, the needle 212 is just leaving the material and the feed dog 280 is just taking hold of the material in order to cause relative movement of the material and the sewing head 234. During the next A," movement of the carriage 220 ;the engagement of the feed dog 280 with the material being sewed causes the sewing head 234 to advance 4" with respect to the material being sewed, thus returning the sewing head to a vertical position. The needle 212 then again enters the material to make a new stitch and the operation is repeated.

It will thus be seen that the advancement of the sewing head 234 is accomplished in part by means of the feed dog 280 which is' a portion of the sewing head mechanism and that the resultant intermittent advancement of the sewing head thereby effected is synchronized with the continuous and uniform advancement of the sewing head carriage 220.

When the sewing head reaches the end of a bag being sewed, the feed dog 280 is ineffective to change the position of the sewing head, due to the fact that it is no longer in engagement with material to be sewed. At this time the spring 21lc returns the sewing head to the vartical position. The spring 21lc also permits the sewing head to yield at the time it engages the top of a new bag whenver this engagement occurs at such time that the feeding mechanism is not quite ready to receive the bag and this serves to prevent the sewing head 234 from crumpling or bending the top of the bag, which it might otherwise do.

This action accomplishes a step-by-step motion of the sewing head with a minimum of inertia efiect. This yielding mounting of the sewing head just described is an extremely important feature of my invention and is of utility whether the head moves across a stationary bag as in the present instance or whether the pivots 210 and 21! are held stationary while a bag is moved through the head.

Tape-applying mechanism When a bag is stitched, the holes in the paper 

